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Chapter 25: Problem 1

During lightning strikes from a cloud to the ground, currents as high as 25,000 A can occur and last for about 40 ms. How much charge is transferred from the cloud to the earth during such a strike?

Short Answer

Expert verified
1,000 Coulombs of charge is transferred.

Step by step solution

01

Understand the Problem

The problem involves calculating the amount of electric charge transferred during a lightning strike. The lightning current is given as 25,000 A and it lasts for 40 ms (milliseconds). We will use the formula for electric charge, which is the product of current and time.
02

Convert Time to Seconds

The time given is in milliseconds (ms). To use in the formula, convert it to seconds. Since 1 second = 1000 milliseconds, 40 ms = 40/1000 = 0.04 seconds.
03

Use the Formula for Charge

The formula to calculate the electric charge transferred is:\[ Q = I imes t \]where \( Q \) is the charge (in Coulombs), \( I \) is the current (in Amperes), and \( t \) is the time (in seconds). Substitute the known values: \( I = 25,000 \, A \) and \( t = 0.04 \, seconds \).
04

Calculate the Charge

Substitute the values into the formula:\[ Q = 25,000 \, A imes 0.04 \, s = 1,000 \, C \]So, the charge transferred during the lightning strike is 1,000 Coulombs.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Understanding Lightning Strike Current
Lightning is an impressive natural phenomenon and involves enormous electric currents. When lightning strikes, it results from a rapid discharge of electric charge accumulated in the clouds. The current in a lightning strike can reach extremely high values, typically ranging from thousands to tens of thousands of Amperes, like the 25,000 Amperes mentioned in the exercise.

This high current is the result of the massive buildup of electric charge in the cloud and its sudden release during a strike. This discharge causes the current to spike and, despite lasting only a brief moment, it is powerful and can transfer a significant amount of electric charge. Knowing the current helps in understanding how much electric power is being transferred from the cloud to the ground, which is a crucial factor in calculating the electric charge transferred.
Exploring the Electric Charge Formula
Electric charge is a fundamental property of matter and is measured in Coulombs (C). To calculate the amount of electric charge transferred in any process, you use the formula:
  • \[ Q = I \times t \]
where:
  • \( Q \) is the electric charge in Coulombs,
  • \( I \) is the current in Amperes,
  • \( t \) is the time in seconds.
This formula is based on the relationship that charge is equal to the product of current (flow of electric charge) and the time the current flows.

Essentially, if you have a steady flow of current that lasts for a particular duration, this formula gives you the total electric charge transferred during that time period. For instance, if a 25,000 Ampere current flows for 0.04 seconds, the charge transferred is \( 25,000 \times 0.04 = 1,000 \) Coulombs.
Converting Time to Seconds
Understanding time conversion is crucial when working with formulas as they often require consistent units. In the context of the exercise, the duration of the lightning strike is given in milliseconds (ms), a unit often used to measure very brief periods of time. However, to use this duration in the electric charge formula, we need to convert it to seconds.

The conversion is straightforward.
  • Since 1 second equals 1,000 milliseconds, the time conversion is simply dividing the milliseconds by 1,000.
  • For instance, 40 milliseconds becomes \( 40/1000 = 0.04 \) seconds.


By ensuring we convert any given time into seconds, we maintain consistency and accuracy in calculations involving electric charge, making it easier to apply formulas correctly and arrive at the right solution.

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Most popular questions from this chapter

Electric eels generate electric pulses along their skin that can be used to stun an enemy when they come into contact with it. Tests have shown that these pulses can be up to 500 V and produce currents of 80 mA (or even larger). A typical pulse lasts for 10 ms. What power and how much energy are delivered to the unfortunate enemy with a single pulse, assuming a steady current?

An overhead transmission cable for electrical power is 2000 m long and consists of two parallel copper wires, each encased in insulating material. A short circuit has developed somewhere along the length of the cable where the insulation has worn thin and the two wires are in contact. As a power-company employee, you must locate the short so that repair crews can be sent to that location. Both ends of the cable have been disconnected from the power grid. At one end of the cable (point \(A\)), you connect the ends of the two wires to a 9.00-V battery that has negligible internal resistance and measure that 2.86 A of current flows through the battery. At the other end of the cable (point \(B\)), you attach those two wires to the battery and measure that 1.65 A of current flows through the battery. How far is the short from point A?

A heart defibrillator is used to enable the heart to start beating if it has stopped. This is done by passing a large current of 12 A through the body at 25 V for a very short time, usually about 3.0 ms. (a) What power does the defibrillator deliver to the body, and (b) how much energy is transferred?

Current passes through a solution of sodium chloride. In 1.00 s, \(2.68 \times 10^{16}\) Na\({^+}\) ions arrive at the negative electrode and \(3.92 \times 10^{16}\) Cl\({^-}\) ions arrive at the positive electrode. (a) What is the current passing between the electrodes? (b) What is the direction of the current?

A 1.50-m cylindrical rod of diameter 0.500 cm is connected to a power supply that maintains a constant potential difference of 15.0 V across its ends, while an ammeter measures the current through it. You observe that at room temperature (20.0\(^\circ\)C) the ammeter reads 18.5 A, while at 92.0\(^\circ\)C it reads 17.2 A. You can ignore any thermal expansion of the rod. Find (a) the resistivity at 20.0\(^\circ\)C and (b) the temperature coefficient of resistivity at 20\(^\circ\)C for the material of the rod.
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